Fixing the Electron Shell Positions 1
Introduction
The electron shells can be fixed by noting the exponential decay of my F or T wave and the linear decay for my V or W wave.
Noting where the peaks of my V wave exist within the range between these two waves to determine sites at which the electrons can orbit an atom's nucleus.
Fixing the Electron Shell Positions.
I believe the peaks of the W wave (possibility interacting with those of the V wave) signal the distances for the shells of the electrons.
I have chosen the W wave because it has multiple peaks in preference to the V wave.
Further when I look at the possible shells I see that there are no p, d, or f shells for the first shell region. This suggests to me that the F or T forces are influencing the situation too. The nearer the nucleus the stronger the V and W forces need to be to counteract the F force.
This may give some indication of their relative sizes.
If we look at the diagram for the “Region available for Sites of Electron Shells”
I have shown the T wave as decaying exponentially. There are several ways this may occur. Firstly, the T wave may be inversely proportional to the distance from the nucleus squared. Secondly, the T wave may be decaying at the rate given by the hyperbola y = 1/x. As long as the principle of exponential decay for one force and linear decay for the other is accepted the model will work fine.
This gives a shaded area in which the peaks of the W wave are the only places where matter can congregate.
Returning to the V wave and the orbit of electrons you can see that the troughs represent regions which are 'hostile' to matter collecting. Perhaps this may reflect that the V wave represents an energy to mass conversion cycle and so the peaks indicate maximum energy ( and this is attractive to mass in the form of an electron).
I have chosen the shell arrangement for an atom with a very large atom mass so that the arrangement for the V wave can be tested and be seen to be adequate. This arrangement also allows you to explain the absence or presence of certain shell positions for any atom.
An electron between these peaks rather than be pushed or flipped slightly in 4D will move towards the nearest outer peak.
Arrangement of Electron Shells in Lawrencium (Lr)
